Michal Amitsur scite author profile

Host tRNAs cleaved near the anticodon occur specifically in T4‐infected Escherichia coli prr strains which restrict polynucleotide kinase (pnk) or RNA ligase (rli) phage mutants. The cleavage products are transient with wt but accumulate in pnk‐ or rli‐ infections, implicating the affected enzymes in repair of the damaged tRNAs. Their roles in the pathway were elucidated by comparing the mutant infection intermediates with intact tRNA counterparts before or late in wt infection. Thus, the T4‐induced anticodon nuclease cleaves lysine tRNA 5′ to the wobble position, yielding 2′:3′‐P greater than and 5′‐OH termini. Polynucleotide kinase converts them into a 3′‐OH and 5′ P pair joined in turn by RNA ligase. Presumably, lysine tRNA depletion, in the absence of polynucleotide kinase and RNA ligase mediated repair, underlies prr restriction. However, the nuclease, kinase and ligase may benefit T4 directly, by adapting levels or decoding specificities of host tRNAs to T4 codon usage.

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The optional E. coli prr locus encodes a latent form of phage T4-induced anticodon nuclease.

Levitz

et al. 1990

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The optional Escherichia coli prr locus restricts phage T4 mutants lacking polynucleotide kinase or RNA ligase. Underlying this restriction is the specific manifestation of the T4-induced anticodon nuclease, an enzyme which triggers the cleavage-ligation of the host tRNALYS. We report here the molecular cloning, nucleotide sequence and mutational analysis of prr-associated DNA. The results indicate that prr encodes a latent form of anticodon nuclease consisting of a core enzyme and cognate masking agents. They suggest that the T4-encoded factors of anticodon nuclease counteract the prr-encoded masking agents, thus activating the latent enzyme. The encoding of a tRNA cleavage-ligation pathway by two separate genetic systems which cohabitate E.coli may provide a clue to the evolution of RNA splicing mechanisms mediated by proteins.

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PrrC-anticodon nuclease: functional organization of a prototypical bacterial restriction RNase

Blanga-Kanfi

Amitsur

Azem

et al. 2006

Nucleic Acids Research

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The tRNALys anticodon nuclease PrrC is associated in latent form with the type Ic DNA restriction endonuclease EcoprrI and activated by a phage T4-encoded inhibitor of EcoprrI. The activation also requires the hydrolysis of GTP and presence of dTTP and is inhibited by ATP. The N-proximal NTPase domain of PrrC has been implicated in relaying the activating signal to a C-proximal anticodon nuclease site by interacting with the requisite nucleotide cofactors [Amitsur et al. (2003) Mol. Microbiol., 50, 129–143]. Means described here to bypass PrrC's self-limiting translation and thermal instability allowed purifying an active mutant form of the protein, demonstrating its oligomeric structure and confirming its anticipated interactions with the nucleotide cofactors of the activation reaction. Mutagenesis and chemical rescue data shown implicate the C-proximal Arg320, Glu324 and, possibly, His356 in anticodon nuclease catalysis. This triad exists in all the known PrrC homologs but only some of them feature residues needed for tRNALys recognition by the Escherichia coli prototype. The differential conservation and consistent genetic linkage of the PrrC proteins with EcoprrI homologs portray them as a family of restriction RNases of diverse substrate specificities that are mobilized when an associated DNA restriction nuclease is compromised.

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Detection of anticodon nuclease residues involved in tRNALys cleavage specificity

Meidler

Morad

Amitsur

et al. 1999

Journal of Molecular Biology

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Bacteriophage T4‐encoded Stp can be replaced as activator of anticodon nuclease by a normal host cell metabolite

Amitsur

Schwessinger

Rosner

et al. 2003

Molecular Microbiology

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SummaryThe bacterial tRNA Lys -specific anticodon nuclease is known as a phage T4 exclusion system. In the uninfected host cell anticodon nuclease is kept latent due to the association of its core protein PrrC with the DNA restriction-modification endonuclease EcoprrI. Stp, the T4-encoded peptide inhibitor of EcoprrI activates the latent enzyme. Previous in vitro work indicated that the activation by Stp is sensitive to DNase and requires added nucleotides. Biochemical and mutational data reported here suggest that Stp activates the latent holoenzyme when its EcoprrI component is tethered to a cognate DNA substrate. Moreover, the activation is driven by GTP hydrolysis, possibly mediated by the NTPase domain of PrrC. The data also reveal that Stp can be replaced as the activator of latent anticodon nuclease by certain pyrimidine nucleotides, the most potent of which is dTTP. The activation by dTTP likewise requires an EcoprrI DNA substrate and GTP hydrolysis but involves a different form of the latent holoenzyme/DNA complex. Moreover, whereas Stp relays its activating effect through EcoprrI, dTTP targets PrrC. The activation of the latent enzyme by a normal cell constituent hints that anticodon nuclease plays additional roles, other than warding off phage T4 infection.

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Michal Amitsur

Bacteriophage T4 anticodon nuclease, polynucleotide kinase and RNA ligase reprocess the host lysine tRNA.

The optional E. coli prr locus encodes a latent form of phage T4-induced anticodon nuclease.

PrrC-anticodon nuclease: functional organization of a prototypical bacterial restriction RNase

Detection of anticodon nuclease residues involved in tRNALys cleavage specificity

Bacteriophage T4‐encoded Stp can be replaced as activator of anticodon nuclease by a normal host cell metabolite

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